Synthesis of undoped and Fe doped nanoparticles of TiO2 via co-precipitation technique and their characterizations

“…The Fe-TiO 2 band gap energy was determined to be 3.35 and 3.25 eV. It is well suited for energy harvesting and storage applications due to its straight bandgap [39]. It was discovered that charge trapping states caused by doping were more important than the average particle size and energy gap.…”

A Review on Electrospun PVDF-Doped Metal Oxide Nanoparticles for Sensor Applications

“…The Fe-TiO 2 band gap energy was determined to be 3.35 and 3.25 eV. It is well suited for energy harvesting and storage applications due to its straight bandgap [39]. It was discovered that charge trapping states caused by doping were more important than the average particle size and energy gap.…”

A Review on Electrospun PVDF-Doped Metal Oxide Nanoparticles for Sensor Applications

“…7 Furthermore, the introduction of Fe 3+ ions into the crystal structure of TiO 2 has the potential to create and stabilize oxygen vacancies, leading to an effective photocatalytic capability. 8 Various methods have been employed to introduce Fe 3+ ions into TiO 2 lattices, including sol−gel, 9 coprecipitation 11 techniques. While these methods demand prolonged reaction periods, often up to 24 h, flame spray pyrolysis (FSP) offers a faster alternative for producing metal oxide nanoparticles.…”

“…Various methods have been employed to introduce Fe 3+ ions into TiO 2 lattices, including sol–gel, hydrothermal, and coprecipitation techniques. While these methods demand prolonged reaction periods, often up to 24 h, flame spray pyrolysis (FSP) offers a faster alternative for producing metal oxide nanoparticles.…”

Synthesis of Pure and Fe-Doped TiO₂ Nanoparticles via Electrospray-Assisted Flame Spray Pyrolysis for Antimicrobial Applications

New investigation of nanosized co-doped Gd-Sm anatase TiO2 structural, magnetic, optical, and first-principles study